Spinous process device

ABSTRACT

A spinal device in which a plate is placed on both sides of the lamina spinous process. The plates include horizontal and diagonal slots through which anchoring screws may be placed and secured. The screws may pass through the base of the spinous process and lamina structure. The plates may have cut-out portions on the ventral side to accommodate the lamina when reduction is performed. The diagonal slots preferably have an apex proximate to the dorsal side and open at the ventral side. The two plates can be mirror images of each other, and, when secured together by the screws, forms a stable construct that can sandwich the spinous process.

CROSS-REFERENCES TO RELATED APPLICATIONS

This is a continuation application based on U.S. Ser. No. 13/311,542,filed on Dec. 5, 2011, which claims priority from provisional U.S.Application No. 61/419506, filed Dec. 3, 2010 and provisional U.S.Application No. 61/480349, filed Apr. 28, 2011, each incorporated byreference in its entirety.

FIELD OF THE INVENTION

The present invention relates generally to orthopedic devices. Morespecifically, the present invention relates to orthopedic devices forthe spinous process.

BACKGROUND

Spinal surgery is a common medical procedure in the United States andthroughout the world. Spinal surgery is typically performed todecompress nerves and/or to stabilize the spinal elements. Spinalsurgery can involve either anterior or posterior approaches to thespine. There are variations in the spinal anatomy of the cervical,thoracic, and lumbar levels of the spine. However, there are commonanatomical elements of the spine at all the levels. The anterior boneelements of the spine include the vertebral bodies, with the interposedintervertebral discs. The posterior bone elements of the spine includethe lamina, the spinous processes, the facet joints, the pedicles, andthe transverse processes. Several ligaments, including the anteriorlongitudinal ligament, the posterior longitudinal ligament, theligamentum flavum (or interlaminar ligament) and the interspinousligament provide fibrous connections between the bone elements andcontribute to the mechanical stability of the spine.

The spinous process of a vertebra is directed backward and downward fromthe junction of the laminae, and serves for the attachment of musclesand ligaments. The spinous process may be described as the protrusion onthe center of the back of a vertebral body. The spinous process is thebone that can be felt down one's back. The paired transverse processesare oriented 90 degrees to the spinous process and provide attachmentfor back muscles.

Spondylolisthesis is a condition in which a bone (vertebra) in the lowerpart of the spine slips out of the proper position onto the bone belowit, such as an anterior slip of a vertebrae in relation to the vertebraeimmediately below it. In degenerative spondylolisthesis, the forwardtranslation of the vertebral body may also cause narrowing of thecentral spinal canal at the level of the slip. The narrowing of thecanal in degenerative spondylolisthesis has been referred to as the“napkin ring effect.” An illustrative description as one imagines thespinal canal as a series of napkin rings with one of the rings slidforward in comparison to the others. Subluxation of the upper adjacentvertebrae to the one below it may cause degenerative spondylolisthesis.The levels generally involved in the pathology include 90% at L4-L5, and8% at L3-L4 and 2% at L5-S 1. The degree of subluxation is less than 50%(grade 1 to 2) without surgery.

Degenerative spondylolisthesis may occur in older patients over fortyyears of age, and in more prevalent in patients over the age of sixty.Aging degenerative may show changes in the interverebral disc of the twovertebra adjacent to each other and the posterior articular process ofthe facet joints. Degenerative spondylolisthesis also is more common infemales than males, and degenerative spondylolisthesis is more common indiabetes patients.

The translation of one vertebra and the other may present with symptomsof stenosis. The disc protrudes posteriorly into the vertebral canal.This may be referred to as a pseudo-herniated disc because of the slip.Degenerative spondylolisthesis may present with symptoms of neurologicclaudication with lumbar spine pain, thigh pain, cramping from prolongedstanding or walking. Treatments may include bracing, anti-inflammatorysteroids, and physical therapy. Surgery including surgical fusion alsomay be employed to stabilize the segment and decompress the spine. Thereis a need for a cost-effective treatment that avoids thecontraindications of other treatments.

SUMMARY OF THE INVENTION

Briefly and in general terms, the present invention provides a spinousprocess device in which a plate is placed on both sides of the laminaspinous process. The plates may include horizontal and diagonal slotsthrough which anchoring screws may be placed and secured. The screws maypass through the base of the spinous process and lamina structure. Theplates may have cut-out portions on the ventral side to accommodate thelamina when reduction is performed. When secured together by the screws,the plates can sandwich the spinous process in a stable construct.

In one aspect, the spinal device comprises a first plate having a dorsalside and ventral side, the first plate being substantially flat andhaving an elongated shape. The plate may further have a substantiallyhorizontal slot and a substantially diagonal slot, wherein thesubstantially diagonal slot is proximate to a cut-out portion on theventral side of the first plate, and the cut-out portion beingconfigured to accommodate the lamina; a second plate configured as asubstantially mirror image of the first plate, wherein the horizontalslots and diagonal slots of the first plate and the second plate aresized so as to accommodate anchoring screws such that when the firstplate and the second plate is secured together by the screws, whereinthe spinous process is stabilized by being sandwiched between the firstplate and the second plate.

Other features and advantages of the invention will become more apparentfrom the following detailed description of preferred embodiments of theinvention, when taken in conjunction with the accompanying exemplarydrawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of one embodiment of the invention showingan elongated plate and slots formed therein.

FIG. 2 is a side view of one embodiment of the invention showing anelongated plate and slots formed therein anchored to the spine.

FIG. 3 is a perspective view of a second embodiment of the inventionshowing an elongated plate and slots formed therein.

FIG. 4 is a side view of the second embodiment of the invention showingan elongated plate and slots formed therein anchored to the spine.

FIG. 5 is a perspective view of a third embodiment of the inventionshowing an elongated plate and slots formed therein.

FIG. 6 is a side view of the third embodiment of the invention showingan elongated plate and slots formed therein anchored to the spine.

FIG. 7 is a side view of a fourth embodiment of the invention showing anelongated plate and slots formed therein anchored to the spine.

FIG. 8 is a side view of the fourth embodiment of the invention showingan elongated plate and anchored to the spine at a new location along theslots.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

As illustrated in FIG. 1, in general terms, the present inventionprovides a new and improved spinal process device. Although describedherein for application to the spine, application to other bony anatomicstructures is also contemplated. The concept behind the plate and screwsthrough the spinous process was derived for its simplicity, ease of useand time constraints with minimal complications. Prior intra spinoustechnology has potential drawbacks such as screw loosening, difficultyin properly fitting the plate to the spine, too high placement of theplate, and canal penetration with the screws.

Other spinous process techniques include the use of the spinous processfor fixation of the spine and fusion of the spine with the Triple Bowmanwire technique with cortical cancellous bone strips and wires throughthe spinous process. Another technique used the Drummond buttons, wiresand rods to fix the spine in the cervical, thoracic and lumbar spine.

As illustrated in, for example, FIGS. 1 and 2, one embodiment of thespinous process device 10 has an elongated wedge-like shape. The spinousprocess device 10 may consist of two plates 12 (only one is shown inFIG. 1) which are mirror images of each other. The plate 12 has slots 20formed therein which receive bone screws 40 or other fasteners. Theslots may include substantially horizontal slots 22, 24, 25 and asubstantially diagonal slots 26, 28. The substantially diagonal slot 28is proximate to a cut-out portion 14 on the ventral side of the firstplate 12, and the cut-out portion may be configured to accommodate thelamina or other structure. The diagonal slot 26 is near the top end ofthe plate 12. The substantially horizontal slots 22, 24, 25 are towardsthe bottom end of the plate 12. A second plate (not shown) may beconfigured as a substantially mirror image of the first plate 12. Thehorizontal slots and diagonal slots of the first plate and the secondplate are sized so as to accommodate anchoring screws 40 such that whenthe first plate and the second plate is secured together by the screws40 and nuts 44, as illustrated in FIG. 2. Preferably the horizontal slotis bounded, and the diagonal slot may have one end open to the ventralside of the plate. The substantially diagonal slots preferably includeat least one secondary slot branching away from the apex of the diagonalslot. The apex is preferably located proximate to the dorsal side of theplate.

The two plates, which are mirror images of one another, may extend fromL3 to the sacrum. The plates may be lordotic and wedge-shaped. Thedorsal end is preferably thick or relatively thicker, and the volar endnarrow or relatively narrow with a flare to match the shape of the baseof the spinous process and top of the lamina. From the cephaladdirection the plates preferably are wider, and preferably narrowercaudally. In one embodiment, there are two horizontal slotted holes onthe plate for the L5 and S1 vertebral spinous process lamina structure.In the embodiment, there are two diagonal slotted holes from dorsal toventral at level L3 and L4, and there are two extended slots at L4 andone slot at L3 angling back caudally from the diagonal slots. Theseslots preferably are made to fit three or four mm screws which are usedto anchor the plates to the vertebra for in-situ fusion or to stabilizeand/or minimally reduce the unstable L4 or L3. When the screws aresecured, the two plates sandwich the spinous process lamina to stabilizeit. In the alternative, one may secure fixation of the plate using aslot placed at the L5 spinous process using two horizontal slots overthe plates L5 spinous process.

In another second embodiment, as illustrated in FIGS. 3 and 4, thespinous process device 100 comprising the plate 112 with slots 120(horizontal slots 122, 124 and 125, and diagonal slots 126 and 128) maybe used for spinal reduction. The horizontal slots 122, 124, 125 arebounded located towards the bottom end of the plate, and the diagonalslots 126, 128 are open to the ventral side, and diagonal slots 126 islocated near the top end of the plate. The diagonal slot 128 isproximate to a cut-out portion 114 on the ventral side.

The fusion reduction plates can be used at one level L4 or two levels L3and L4. The reduction plates has cut outs over the lamina of L3 and L4to accommodate the lamina when reduction is performed. The diagonalslots over L4 and L3 have at least one slot at the height of thediagonal slot going caudally for four or five mm. This allows one toanchor the screws on the vertebra to the plates when the spine isreduced. The volar end of the slot at L3 and L4 is open, this is for thereduction screw to gain access to the slot in the plates.

A hole may be made in the base of the spinous process on both sides toallow a screw to pass through and a nut is placed on the other side.Preferably, the plate 112 at L5 is fixed first, and possibly the sacrumas well, with screw 140 and nuts 144. A screw at L4 may then be used toreduce the unstable spine or spondylo by compressing bilaterally. Thescrew may slide up the slot on the plate and may be tightened in placewhen the screw lands on the slot pointing backward. Such a configurationis intended to stop the spine from sliding back down. A stable constructmay be created by tightening the screw and the nuts to the plate andspinous process.

After the distraction the volume of the canal will increase, the facetjoints between L4-L5 will be distracted, and if L3 is reduced, the facetjoints between L3-L4 will also be distracted and open. Now fusion can bedone with facet screw fixation. After the distraction reduction, thereis room for lumbar decompression by doing a laminotomy.

Yet another third embodiment of the plate is for one level distractionreduction at L4-L5 degenerative spondylolisthesis is illustrated inFIGS. 5 and 6. The spinous process device 210 preferably comprises theplate 212 with slots 220 (horizontal slots 222, 224 and 225 located nearboth the top and bottom ends of the plate 212, and at least one diagonalslot 226 open to the ventral side adjacent a cut-out portion 214). HereL4 is lower than L5, and the plates 212 preferably are first fixed to L5and L3 bilaterally with double fixation of plate at the L5 process.Screws 240, such as four mm screws, are inserted through the base of theL4 spinous process. Now distract reduce the spondy by compressing theplate with screw 240 being directed into the slot 214 on the plate overL4 vertebra. The construct may be fixed by tightening the nuts 244 onthe screw 240 to sandwich the spinous process. The volume of the canalwill increase to indirectly decompress the canal. The facet joints willbe distracted and open, then screw fixation of the joints can be donethus obtaining fusion.

Another alternative embodiment of the spinous process device 310 andplate 312 is illustrated in FIGS. 7 and 8. In this embodiment, thediagonal slots 326 and 328 are bounded. The substantially diagonal slotsmay preferably include at least a secondary slot branching away from theapex, which is located proximate to the dorsal side of the plate. Anadditional secondary slot may branch away closer to the midpoint of thediagonal slot. After the screws 340 are secured by the nuts 344, thebone may be placed at different locations along the branched diagonalslot. FIG. 7 illustrates unreduced spondylolisthesis with the spinousprocess plate 312 inserted, and FIG. 8 illustrates reducedspondylolisthesis with the spinous process plate 312.

In the new intra lamina spinous process reduction technique discussedherein, it is preferable that two plates on both sides of the laminaspinous process are used with screws going through the plates on bothsides of the base of the spinous process, lamina structure and the plateon the other side and then the nuts are used to secure the construct.This can be done from L3 to the sacrum. One use of this device is forreduction, stabilization and fusion of degenerative spondylolisthesisand allowing for decompression of the segment and facet fusion. It canalso be used for stabilization and in-situ fusion of the segment.

The embodiments described therefore are to be considered in all respectsas illustrative and not restrictive. Although the present invention hasbeen described in terms of certain preferred embodiments, otherembodiments will be apparent to those of ordinary skill in the art.Accordingly, the scope of the invention is intended to be defined onlyby reference to the appended claims.

1. A spinal device comprising a first plate having a dorsal side, aventral side, a middle portion, a concave surface in a middle portion onthe ventral side of the first plate, and a first hooked slot open to theventral side.
 2. The spinal device of claim 1, wherein the first platefurther includes at least one closed slot formed therein, wherein theclosed slot is closed to both the dorsal and ventral side.
 3. The spinaldevice of claim 1, wherein the first hooked slot is located in a middleportion of the first plate.
 4. The spinal device of claim 1, wherein asecond concave surface is located in a distal portion on the ventralside of the first plate.
 5. The spinal device of claim 1, wherein thefirst plate further includes at least one closed slot formed therein,wherein the closed slot is closed to both the dorsal and ventral side;and a second hooked slot located in a distal portion of the first plate,wherein the second hooked slot is open to the ventral side.
 6. Thespinal device of claim 5, wherein the at least one closed slot is formedin a distal portion of the first plate.
 7. A spinal device comprising afirst plate having a dorsal side, a ventral side, and a first hookedslot comprising at least two horizontal slots branching off from adiagonal slot.
 8. The spinal device of claim 7, wherein the first hookedslot is closed to both the dorsal and ventral side, and the first platefurther includes at least one closed slot formed therein, wherein theclosed slot is closed to both the dorsal and ventral side.
 9. The spinaldevice of claim 7, wherein the first plate further includes a secondhooked slot comprising at least one horizontal slots branching off froma diagonal slot.
 10. The spinal device of claim 9, wherein the secondhooked slot is located in a distal portion of the first plate.
 11. Thespinal device of claim 7, wherein the first plate further includes atleast one closed slot formed therein, wherein the closed slot is closedto both the dorsal and ventral side; and a second hooked slot located ina distal portion of the first plate, wherein the second hooked slot isopen to the ventral side.
 12. The spinal device of claim 11, wherein theat least one closed slot is formed in a distal portion of the firstplate.